Abstract
Post-transcription mRNA processing in the 3’-untranslated region (UTR) of transcripts alters mRNA landscape. Alternative polyadenylation (APA) utilization in the 3’-UTR often leads to shorter 3’-UTR affecting mRNA stability, a process that is regulated by PABPN1. In skeletal muscles PABPN1 levels reduce with age and a greater decrease in found in Oculopharyngeal muscular dystrophy (OPMD). OPMD is a late onset autosomal dominant myopathy caused by expansion mutation in PABPN1. In OPMD models a shift from distal to proximal polyadenylation site utilization in the 3’-UTR, and PABPN1 was shown to play a prominent role in APA. Whether PABPN1-mediated APA transcripts are functional is not fully understood. We investigate nuclear export and translation efficiency of transcripts in OPMD models. We focused on autophagy-regulated genes (ATGs) with APA utilization in cell models with reduced functional PABPN1. We provide evidence that ATGs transcripts from distal PAS retain in the nucleus and thus have reduced translation efficiency in cells with reduced PABPN1. In contrast, transcripts from proximal PAS showed a higher cytoplasmic abundance but a reduced occupancy in the ribosome. We therefore suggest that in reduced PABPN1 levels ATG transcripts from APA may not effectively translate to proteins. In those conditions we found constitutive autophagosome fusion and reduced autophagy flux. Augmentation of PABPN1 restored autophagosome fusion, suggesting that PABPN1-mediated APA plays a role in autophagy in OPMD and in aging muscles.
Highlights
The majority of mammalian genes have more than two PAS, and different PAS utilization generates transcripts that differ in their 3’-untranslated region (UTR) length [1]
PABPN1 is a multifunctional regulator of mRNA processing including poly(A) tail length and Alternative polyadenylation (APA) utilization [8, 9]
To identify autophagy-regulated genes (ATGs) candidates whose mRNA expression levels is altered in Oculopharyngeal muscular dystrophy (OPMD) muscles, we investigated the autophagy gene network (KEGG #4140) in our previous OPMD transcriptome study [15]
Summary
The majority of mammalian genes have more than two PAS, and different PAS utilization generates transcripts that differ in their 3’-UTR length [1]. Genome wide studies revealed that APA utilization can be tissue and cell type-specific, and is associated with human pathologies [1, 4, 5]. PABPN1 is a multifunctional regulator of mRNA processing including poly(A) tail length and APA utilization [8, 9]. Reduced PABPN1 levels increase APA utilization [6, 7, 12]. Whether PABPN1mediated APA utilization leads to functional transcripts that affect protein levels and muscle cell function is not fully understood. Networks of genes of protein catabolism are most prominently dysregulated in OPMD [12, 15]. In previous studies we reported that the proteasome gene network is highly dysregulated in OPMD corroborated with reduced proteasomal activity [14, 16]. We provide the first evidence that autophagy is affected in OPMD
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